Portable power amplifier

ABSTRACT

A portable power amplifier includes portable encapsulating cases ( 62, 63 ), a printed board ( 61 ) incorporated in those encapsulating cases ( 62, 63 ), and a power amplifying device ( 27 ) mounted on this printed board ( 61 ). An antenna switch ( 12 ) and an antenna are provided near the power amplifying device ( 27 ), which is connected to those components in a pattern ( 65 ). This structure improves the heat dissipation efficiency of the portable power amplifier.

TECHNICAL FIELD

The present invention relates to portable power amplifiers to be used in portable apparatuses.

BACKGROUND ART

A conventional portable power amplifier used in portable apparatuses is a simple one because the apparatuses are portable, which regulates the specification of their power amplifiers, so that the power amplifier is not a large size, or does not dissipate the heat efficiently. To be specific, as shown in FIG. 7, power amplifying device 2 is mounted on an upper face of printed board 1 disposed in a portable outer case typically used in a portable phone. The heat generated from amplifying device 2 travels through through-holes 3 and is dissipated from pattern 4 prepared on a rear face of printed board 1. However, in this conventional structure, pattern 4 is limited its size as a heat-sink and can not dissipate the heat sufficiently. A use of a dedicated large heat-sink would enlarge the apparatus and make it unfit for portable use.

DISCLOSURE OF THE INVENTION

A portable power amplifier comprising the following elements is provided:

-   -   a portable outer case;     -   a printed board disposed in the outer case;     -   a power amplifying device mounted to the printed board; and     -   a heat resisting component disposed close to the amplifying         device and coupled to the amplifying device via heat conductive         material.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a sectional view of an essential part of a portable power amplifier in accordance with a first exemplary embodiment of the present invention.

FIG. 2 shows a sectional view of an essential part of a portable power amplifier in accordance with a second exemplary embodiment of the present invention.

FIG. 3 shows a sectional view of an essential part of a portable power amplifier in accordance with a third exemplary embodiment of the present invention.

FIG. 4 shows a sectional view of an essential part of a portable phone employing the portable power amplifier in accordance with the third exemplary embodiment of the present invention.

FIG. 5 is a block diagram illustrating a vicinity of a power amplifying device in accordance with a fourth exemplary embodiment of the present invention.

FIG. 6 is a block diagram of a portable phone employing a portable power amplifier of the present invention.

FIG. 7 shows a sectional view of an essential part of a conventional portable power amplifier.

BEST MODE FOR CARRYING OUT THE INVENTION

Exemplary embodiments of the present invention are demonstrated hereinafter, using a portable phone that employs a portable power amplifier, with reference to FIG. 1 through FIG. 6.

EXEMPLARY EMBODIMENT 1

FIG. 6 shows a block diagram of a portable phone employing a portable power amplifier in accordance with the first embodiment of the present invention. In FIG. 6, antenna 11 is coupled to a common terminal of antenna switch 12, which has three outputs and one input switchable upon request. First output from switch 12 is supplied to first quadrature demodulator 15 of GSM (Global System for Mobile communication) band via band pass filter 13 that passes signals of GSM band (900 MHz) and via low noise amplifier (LNA) 14. First demodulator 15 supplies its output to DC offset canceler 16. A first output from voltage control oscillator (VCO) 17 is supplied to another input terminal of first demodulator 15.

A second output from antenna switch 12 is supplied to second quadrature demodulator 20 of DCS band (1800 MHz) via band pass filter 18 that passes signals in the DCS band and via LNA 19. Then demodulator 20 supplies the output to DC offset canceler 16. A second output from VCO 17 is supplied to another input terminal of second quadrature demodulator 20.

A third output from antenna switch 12 is supplied to third quadrature demodulator 23 of PCS band (1900 MHz) via band pass filter 21 that passes signals of the PCS band and via LNA 22. Demodulator 23 supplies the output to DC offset canceler 16. A third output from VCO 17 is supplied to another input terminal of third quadrature demodulator 23.

An output from DC offset canceler 16 is supplied to processing circuit 24 that includes a base-band signal processing circuit, an AD conversion circuit and a DA conversion circuit. An output from processing circuit 24 is supplied to PLL circuit 26 via quadrature demodulator 25. An output from PLL circuit 26 is supplied to VCO 17 for controlling VCO 17. An output from VCO 17 is supplied to an input terminal of antenna switch 12 via power amplifying device (hereinafter referred to simply as PA) 27. An output level of PA 27 is detected by power detection circuit 28, and fed back to processing circuit 24.

PA 27 amplifies an input of ca. 3 mW approx. 1300 times and outputs a signal of ca. 4 W. PA 27 thus needs a large power, and its heat dissipation capacity is raised as a problem in order to gain the output efficiently. The present invention addresses mainly PA 27, VCO 17, antenna switch 12 and the vicinity of antenna 11.

FIG. 1 shows a sectional view of an essential part of the portable power amplifier in accordance with the first exemplary embodiment of the present invention. In FIG. 1, PA 27, antenna switch 12, connector 32 coupled to antenna 11 and VCO 17 are mounted on a surface of printed board 31. Metallic partition plate 33 is vertically disposed between PA 27 and VCO 17 and separates VCO 17 thermally from PA 27 for preventing VCO 17 from adversely influencing PA 27 with its frequency deviation, level changes, phase noises, and oscillation stop.

The heat generated from PA 27 travels to pattern 35 (used as an example of heat conductive material) formed on the rear face of printed board 31 via through-holes 34. Pattern 35 is disposed adjacent to a heat resisting outer case of antenna switch 12 as well as to antenna switch 12 per se, and coupled to heat resisting connector 32.

As such, antenna switch 12 and connector 32 are placed close to PA 27, thereby reducing heat resistance of pattern 35. As a result, antenna 11 and antenna switch 12 can efficiently dissipate the heat of PA 27. Pattern 35 is preferably as wide or thick as possible in order to reduce its heat resistance. The number of through-holes 34 is preferably as many as possible because of the same reason.

In the case that a multi-layer board is used as printed board 31, pattern 35 is preferably prepared as the first layer so that the heat resistance can be lowered. FIG. 1 dose not show an outer case; however, a case covering printed board 31 is actually available. In this embodiment a rod antenna is used as antenna 11; however, an antenna formed of chip components can be used. Antenna 11 can be exposed from the outer case, and this exposure substantially increases the heat dissipation performance. The surface of pattern 35 is roughed in advance by buffing or chemical polishing, so that the pattern formed of copper foil dissipates the heat with ease.

Chip capacitor 36 is mounted close to PA 27 and works to cut off a current or reduce noises of the power supply (capacitor 36 is hereinafter referred to as a bypass capacitor). Since capacitor 36 is placed close to PA 27, its capacitance can be changed by the heat from PA 27. However, this change does not affect the work of capacitor 36 because capacitor 36 just cuts of the current or reduces the noises. Thus chip capacitor 36 placed close to PA 27 can dissipate the heat from PA 27 without losing its high-frequency performance.

EXEMPLARY EMBODIMENT 2

FIG. 2 shows a sectional view of an essential part of a portable power amplifier in accordance with the second exemplary embodiment. In FIG. 2, soldering section 42 is disposed on a side face of printed board 41. Power amplifying device (PA) 27, antenna switch 12, and VCO 17 are mounted on the surface of printed board 41. Metallic shielding case 43 working as an outer case covers all the components mounted on printed board 41. The heat generated from PA 27 travels to pattern 45 formed on the rear face of printed board 41 via through-holes 44. Pattern 45 is coupled to soldering section 42. As such, pattern 45 is coupled to heat resisting shielding case 43 via an outer case of antenna switch 12, antenna switch 12 per se and soldering section 42.

The heat generated from PA 27 can be dissipated efficiently from shielding case 43 prepared for shielding the electronics components, the outer case of antenna switch 12, and antenna switch 12 per se.

Pattern 45 is preferably as thick or wide as possible in order to reduce its heat resistance. The number of through-holes 44 is preferably as many as possible because of the same reason. Antenna switch 12 is disposed close to soldering section 42 and adjacent to PA 27. In the case that a multi-layer board is used as printed board 41, pattern 45 is preferably prepared as the first layer so that the heat resistance can be lowered. In FIG. 2, no outer case is shown; however, an outer case for covering the shielding case 43 is actually available.

Top plate 47 of shielding case 43 at PA 27 side is bent, thereby forming partition plate 48, which separates VCO 17 thermally from PA 27. This separation can reduce adverse influence from VCO 17 such as frequency deviation, level changes, phase noises, and oscillation stop. Hole 49 is formed on shielding case 43 at PA 27 side, and this hole 49 can dissipates the heat from PA 27.

Part of top plate 47 of shielding case 43 above PA 27 is cut and bent to form slip 50, then slip 50 is elastically urged against a top plate of PA 27. This structure allows shielding case 43 to dissipate directly the heat from PA 27, thereby obtaining an advantage of heat-dissipation.

Further, side face 46 of shielding case 43 is roughed, thereby enlarging the surface area for increasing the heat dissipation efficiency. Top plate 47 is smoother than side face 46 and can be sucked with a nozzle, thereby handling the amplifier with ease, and case 43 looks fine on the top plate.

Burr 51 is formed at the end of side face 46 toward soldering section 42, so that space 52 is produced between side face 46 and soldering section 42. Therefore, space 52 is positively filled with solder due to a capillary action in soldering, so that soldering section 42 is jointed with shielding case 43 with a large area. As a result, heat resistance due to the joint between pattern 45 and case 43 is reduced, and the heat dissipation thus can be increased.

In manufacturing shielding case 43, a metal plate is cut by punching thereby forming burr 51 at the end of side face 46, then the plate is bent at the right angle in the cutting direction, so that side face 46 is formed.

Intake hole 53 is prepared on case 43, for outer air to flow-in, near to VCO 17 at soldering section 42 side. Outlet hole 54 is prepared on case 43 near to PA 27. Cool outer air flows in through intake hole 53, thereby cooling VCO 17 that has been warmed by PA 27. Then the air flows out through outlet hole 54. This structure prevents VCO 17 from lowering its performances (such as degradation of phase noises, oscillation stop, or frequency deviation) due to the heat.

EXEMPLARY EMBODIMENT 3

FIG. 3 shows a sectional view of essential parts of a portable phone in accordance with the third exemplary embodiment. In FIG. 3, power amplifying device (PA) 27, antenna switch 12, and VCO 17 are mounted on the surface of printed board 61. Heat resisting encapsulating cases 62 and 63 cover all the components mounted on printed board 61. The heat generated from PA 27 travels to heat conductive pattern 65 formed on the rear face of printed board 61 via through-holes 64. Pattern 65 is coupled to encapsulating cases 62 and 63 to which heat conductive material is attached, so that pattern 65 is thermally coupled to overall surfaces of encapsulating cases 62 and 63. As a result, pattern 65 is coupled to an outer case of antenna switch 12 disposed adjacent to PA 27 and encapsulating cases 62, 63 disposed adjacent to antenna switch 12.

The heat generated from PA 27 can be dissipated from encapsulating cases 62, 63 prepared for protecting the electronics components. A placement of junction point 66 of antenna switch 12, encapsulating cases 62 and 63 close to PA 27 reduces the routing of pattern 65. Then heat resistance is lowered, and the heat of PA 27 can be dissipated efficiently from encapsulating cases 62, 63 and antenna switch 12. Pattern 65 is preferably as thick as possible in order to reduce its heat resistance. The number of through-holes 64 is preferably as many as possible because of the same reason. In the case that a multi-layer board is used as printed board 61, heat conductive pattern 65 is preferably prepared as the first layer so that the heat resistance can be lowered.

FIG. 4 shows a sectional view of essential parts of the portable phone in accordance with the third embodiment. In FIG. 4, first hole 71 is provided to encapsulating case 63 such that hole 71 faces audio input device 70, and second hole 73 is provided to outer case 63 such that hole 73 faces audio output device 72. Power amplifying device (PA) 27 is prepared between audio input device 70 and audio output device 72.

The portable phone discussed above is used such that audio input device 70 is brought close to a user's mouth and audio output device 72 is brought close to the user's ear. As a result, audio input device 70 takes its place below PA 27 and audio output device 72 takes the place above PA 27 when the portable phone is in use. First hole 71 and second hole 73 are thus placed such that they face audio input device 70 and audio output device 72 respectively. Therefore, air flows in through first hole 71 opposite to audio input device 70, and flows out through second hole 73 opposite to audio output device 72. This mechanism allows open air to flow into outer cases 62 and 63 through first hole 71 of audio input device 70, and heated air to flow out through second hole 73 of audio output device 72, so that PA 27 can be cooled down.

Providing PA 27 with spaces 52 shown in FIG. 2 above and below PA 27 will further cool down PA 27.

EXEMPLARY EMBODIMENT 4

FIG. 5 is a block diagram illustrating a vicinity of the portable power amplifier in accordance with the fourth exemplary embodiment. In FIG. 5, an output from VCO 17 is supplied to input terminal 80 of power amplifying device (PA) 27. Input terminal 80 is coupled to a first matching circuit formed of inductor 81 and chip capacitor 82. Inductor 81 is connected to PA 27 in series, and chip capacitor 82 is connected to PA 27 in parallel. The first matching circuit determines the constants such that the impedance of VCO 17 is matched with PA 27.

An output from PA 27 is supplied to a second matching circuit formed of inductor 83 and chip capacitor 84. Inductor 83 is coupled to PA 27 in series, and chip capacitor 84 is coupled to PA 27 in parallel.

In this fourth embodiment, chip capacitors 82 and 84 are reflow-soldered, so that they make an advantage of self-alignment effect of reflow soldering. As a result, capacitors 82 and 84 are accurately soldered onto the given positions of the pattern free from unnecessary inductance. Thus an excellent power amplifying can be expected, and a portable power amplifier of superb characteristics is obtainable.

An output from the second matching circuit is supplied to directional coupler 85, of which first output is supplied to output terminal 87 via low pass filter 86. Output terminal 87 is coupled to an input terminal of antenna switch 12. A second output from directional coupler 85 is supplied to automatic power control circuit 88, of which output is supplied to power control terminal 27 a of PA 27.

Control terminal 89 regulates an amplification degree of PA 27 from the outside and is coupled to automatic power control circuit 88. Control terminal 90 controls on-off of the power supply of PA 27 from outside and is coupled to an input terminal of circuit 88 and also coupled to power supply control terminal 27 b of PA 27 via circuit 88.

Between circuit 88 and power control terminal 27 a, chip capacitor 91 grounded is coupled, and between circuit 88 and power supply control terminal 27 b chip capacitor 92 grounded is coupled. These capacitors 91 and 92 can attenuate the noises riding on terminals 27 a and 27 b, and since the two capacitors are placed close to PA 27, they can dissipate the heat generated from PA 27.

Chip capacitors 91 and 92 are reflow-soldered and thus heat resistive, therefore, they can be used close to PA 27 without any problem. Since chip capacitors 91 and 92 are used to attenuate noises, the function of attenuating high-frequency noises is not damaged even if the capacitance is somewhat varied by the heat from PA 27, and a stable amplification is obtainable.

Chip capacitors 82 and 84 are elements of first and second matching circuits respectively. Respective one of electrodes of capacitors 82 and 84 are grounded near to shielding case 47 as shown in FIG. 2. This structure allows the heat of PA 27 to dissipate from shielding case 47 via the grounding and capacitors 82 and 84.

This structure also suppresses the temperatures of capacitors 82 and 84 to rise, so that changes of the impedance of the matching circuits due to temperature drift can be suppressed. As a result, a signal loss due to the heat generated from Pa 27 can be minimized.

Instead of the second matching circuit, low pass filter 86 can be directly coupled to an output terminal of PA 27. In this case, the chip capacitor that is an element of filter 86, and of which one of the electrodes is grounded, is preferably placed close to shielding case 47. The chip capacitor is reflow-soldered and thus accurately positioned, which assures to produce a low pass filter having a stable cut-off frequency and being less affected by temperature.

Instead of chip inductor 81,83, a pattern inductor can be used. And an inductor that is an element of low pass filter 86 can be used as a pattern inductor. In this case, the pattern inductor can dissipate the heat, and is strong enough to withstand vibrations or shocks. Further, it can be adjusted to a given inductance by laser trimming, so that an accurate portable power amplifier is obtainable.

In the case that when input terminal 80 receives an output from an oscillator of open-collector, a dc is applied to terminal 80 in order to power the oscillator. In this case the dc should be prevented from applying to PA 27, so that a dc cut-off capacitor is disposed between input terminal 80 and PA 27. Since this capacitor can just cut off the dc, it keeps working even if the heat from PA 27 changes its capacitance somewhat. This dc cut-off capacitor is inserted between input terminal 80 and PA 27, so that it is placed close to PA 27, thereby dissipating the heat of PA 27.

As discussed above, the portable power amplifier of the present invention comprises the following elements:

-   -   a portable outer case;     -   a printed board disposed in the outer case; and     -   a power amplifying device mounted to the printed board.

A heat resisting component is disposed in the vicinity of the power amplifying device, and coupled to the power amplifying device via heat conductive material, so that the heat resisting component has two functions, namely, the component for itself and a heat sink. As a result, the heat can be well dissipated and also the portable power amplifier can be downsized without having an independent heat sink that would enlarge the portable power amplifier.

Since the power amplifying device is mounted on the printed board, the printed pattern can be fully utilized as heat conductive material, so that the portable power amplifiers can be manufactured with ease. The structure discussed above allows eliminating a heat sink from the printed board, so that wiring can be designed with ease and the number of components can be reduced.

Industrial Applicability

The present invention relates to a portable power amplifier to be used in portable apparatuses, and aims to provide a portable power amplifier that can dissipate the heat efficiently and can be fit in the portable apparatuses without changing sizes of the apparatuses. 

1. A portable power amplifier comprising: a portable outer case; a printed board disposed in said outer case; a power amplifying device mounted to said printed board; and a heat resisting component disposed in a vicinity of said power amplifying device and coupled to said power amplifying device via heat conductive material.
 2. The portable power amplifier of claim 1, wherein said heat resisting component is an antenna radiating a high frequency radio wave.
 3. The portable power amplifier of claim 2, wherein the antenna is exposed from said outer case.
 4. The portable power amplifier of claim 1, wherein said heat resisting component is provided to said printed board where said power amplifying device is mounted.
 5. The portable power amplifier of claim 1, wherein said heat resisting component is an antenna switch coupled between an antenna that radiates a high frequency radio wave and said power amplifying device.
 6. The portable power amplifier of claim 1, wherein said heat resisting component is a chip component provided to on said printed board where said power amplifying device is mounted.
 7. The portable power amplifier of claim 1, wherein said heat resisting component is a shielding case for covering an electronic component provided to said printed board where said power amplifying device is mounted.
 8. The portable power amplifier of claim 7, wherein a soldering section is provided to a side face of said printed board, the shielding case covers said printed board entirely, and burr protruding toward the soldering section is provided to a side face of the shielding case.
 9. The portable power amplifier of claim 8, wherein the side face of the shielding case is rougher than a top plate thereof.
 10. The portable power amplifier of claim 8, wherein part of a top plate of the shielding case is cut and bent, and the part is brought into contact with a top plate of said power amplifying device.
 11. The portable power amplifier of claim 8, wherein a high frequency circuit is provided in a vicinity of said power amplifying device, part of a top plate of the shielding case is cut and bent for partitioning said power amplifying device from the high frequency circuit, and a hole produced by the cutting and bending is formed on said power amplifying device side.
 12. The portable power amplifier of claim 11, wherein an air intake hole is provided on a side where the high frequency circuit is disposed and on a side face of the shielding case at a vicinity of the soldering section, and an air outlet hole is provided on a top plate of the shielding case at a vicinity of said power amplifying device.
 13. The portable power amplifier of claim 11, wherein the high frequency circuit is a voltage controlling oscillator.
 14. The portable power amplifier of claim 1, wherein said heat resisting component is the outer case to which heat conductive material is provided.
 15. The portable power amplifier of claim 6, wherein a chip capacitor is inserted between one of a power control terminal and a power supply terminal of said power amplifying device, and grounding.
 16. The portable power amplifier of claim 6, wherein a dc cut-off chip capacitor is coupled in series to one of an input terminal and an output terminal of said power amplifying device.
 17. The portable power amplifier of claim 6 further comprising a filter coupled to an output terminal of said power amplifying device, wherein the filter includes a plurality of chip components, at least one of the chip components is inserted between the output terminal and grounding, and the grounding is prepared on a closer side to a metallic shielding case.
 18. The portable power amplifier of claim 17, wherein the filter has a chip inductor coupled to the output terminal of said power amplifying device, and the chip inductor is reflow-soldered to said printed board.
 19. The portable power amplifier of claim 17 further comprising an inductor coupled to the output terminal of said power amplifying device, wherein the inductor is a pattern inductor.
 20. The portable power amplifier of claim 1, wherein said heat resisting component is copper foil.
 21. The portable power amplifier of claim 20, wherein the copper foil has a rough surface.
 22. The portable power amplifier of claim 20 further comprising an impedance matching circuit coupled to one of an input terminal and an output terminal of said power amplifying device, wherein the matching circuit includes a pattern inductance.
 23. The portable power amplifier of claim 20 further comprising an impedance matching circuit coupled to one of an input terminal and an output terminal of said power amplifying device, wherein the matching circuit includes a plurality of chip components that are reflow-soldered.
 24. The portable power amplifier of claim 23, wherein at least one of the chip components is grounded, and the grounding is provided close to a metallic shielding case.
 25. The portable power amplifier of claim 6, the chip component is a dc cut-off capacitor.
 26. The portable power amplifier of claim 6, wherein the chip component is a bypass capacitor for preventing noises of a power supply.
 27. The portable power amplifier of claim 7, wherein a space is provided between an end of said printed board and an end of the shielding case disposed above the end of said printed board.
 28. The portable power amplifier of claim 25, wherein said printed board is placed such that a space is provided above and below said power amplifying device respectively.
 29. The portable power amplifier of claim 1 further comprising an audio input device and an audio output device that is disposed above the audio input device, wherein said printed board is provided between the audio input device and the audio output device. 